浸没燃烧技术处理高浓度有机废水研究

针对现阶段高浓度有机废水处理困难的问题,提出了一种基于浸没燃烧技术的处理方法,设计制作了1台浸没燃烧装置,并开展了高浓度有机废水浸没燃烧实验研究,探究了过量空气系数、二次风量、燃烧温度等参数对燃烧尾气中CO、NOx排放的影响,以及浸没深度、燃烧温度对高浓度有机废水COD去除的影响。实验结果表明:该工艺对高浓度有机废水中的有机物去除效果明显,温度在900℃以上,浸没深度达到20 cm时,COD去除率可达90%以上。该方法可作为废水处理设备,与生物法等处理技术联用,应用前景广阔。     

碳酸钙改性硅藻土处理电解锌漂洗废水实验研究

铅锌矿在我国储存量大,电解法生产锌过程中可产生含Zn~(2+)、Pb~(2+)、Cd~(2+)、As5+和Cu~(2+)等重金属离子的漂洗废水。以硅藻土精土为基体,用碳酸钙作为改性剂制备改性硅藻土,对电解锌漂洗废水进行吸附实验研究。结果表明:在反应时间为150 min,碳酸钙改性硅藻土用量为3 g/L,pH为5.46,温度为25℃条件下,对废水进行吸附实验,吸附后废水中的Cu~(2+)和As5+离子浓度低于仪器检测线(0.01 mg/L和0.09 mg/L),Pb~(2+)浓度为0.16 mg/L,吸附后废水中Cu~(2+)、As5+和Pb~(2+)离子浓度均满足GB 25466—2010《铅锌工业污染物排放标准》的排放要求。同时,采用SEM、FTIR、XRD等对碳酸钙改性硅藻土进行表征,进一步探讨了碳酸钙改性硅藻土对重金属的吸附机理。     

β-环糊精/醋酸纤维素纳米纤维的制备及对染料废水的处理

制备了不同β-环糊精(β-CD)含量的醋酸纤维素(CA)纳米纤维膜,并对纤维膜的结构形貌、尺寸分布、孔隙率、比表面积以及纤维膜的力学性能进行表征分析。随后研究了不同β-CD含量、初始浓度、吸附时间下,纳米纤维膜对甲基红染料的截留性能和吸附性能。结果表明:过量(≥30%)的β-环糊精会使纳米纤维产生珠节,纤维的形貌和力学性能变差;吸附试验表明,β-CD的加入提高了CA纳米纤维膜对染料的吸附,MR吸附率可达93.48%,最大平衡吸附量可达181.74 mg/g,比纯CA纳米纤维膜提高了将近40%;此外,染料的截留实验表明,纳米纤维膜对染料的截留效果较差,最大截留率为50.35%。     

不同污水处理工艺N_2O减排方法研究进展

污水处理过程中产生强温室气体N_2O的问题已经受到广泛关注,如何在保证处理效率的同时实现N_2O有效减排成为水处理领域面临的重要问题。综述了传统生物脱氮除磷工艺和同步硝化反硝化、反硝化除磷、厌氧氨氧化等新型污水处理工艺运行过程中N_2O的产生机理、减排方法和减排量,为相关领域的研究人员提供参考。     

进水有机负荷对三级生物滴滤池脱氮除磷的影响

试验采用三级(好氧/兼氧/好氧)多层组合填料生物滴滤池处理模拟生活污水,探索强化脱氮除磷工艺。考察了在相同水力负荷和布水周期下,改变进水有机负荷对COD、NH_4~+-N、TN和TP去除率的影响,并用扫描电镜和X射线衍射(XRD)对填料进行辅助分析。研究结果表明,三级串联生物滴滤池的组合相比传统的单级或两级生物滴滤池反应器处理效果更好。第1级和第2级生物滴滤池去除COD、NH_4~+-N和TN效果较好,贡献率合计分别为93.0%、91.2%和91.4%。第1级和第3级生物滴滤池除磷效果较好,贡献率合计91.4%。有机负荷为0.328~0.392 kg/(m~3·d)时,系统总体去除效果最好。     

氯代挥发性有机物CVOCs催化氧化的研究进展

氯代挥发性有机物(CVOCs)因其性质稳定、反应性差且毒性高,成为目前大气污染物净化技术中的难点。催化氧化法是去除CVOCs最有效的方法之一。对CVOCs催化氧化的研究进行综述,列举实例介绍了各类催化剂对常见CVOCs的催化研究现状,对催化性能、催化剂失活、反应机理等方面进行了详细分析,总结出积碳和氯中毒是催化剂失活的两大主要因素,而载体性质、活性组分分散度、水等对催化性能产生很大影响。最后,展望了未来催化剂的研究重点。     

AOX contamination status and genotoxicity of AOX-bearing pharmaceutical wastewater

Adsorbable organic halogens(AOX) are a general indicator for the total amount of compounds containing organically bonded halogens. AOX concentrations and components were investigated along the wastewater treatment process in four large-scale pharmaceutical factories of China, and genotoxicity based on the SOS/umu test was also evaluated. The results showed that AOX concentrations in wastewater of four factories ranged from 4.6 to 619.4 mg/L, which were high but greatly different owing to differences in the raw materials and products. The wastewater treatment process removed 50.0%–89.9% of AOX, leaving 1.3–302.5 mg/L AOX in the effluents. Genotoxicity levels ranged between 2.1 and 68.0 μg 4-NQO/L in the raw wastewater and decreased to 1.2–41.2 μg 4-NQO/L in the effluents of the wastewater treatment plants(WWTPs). One of the main products of factory I, ciprofloxacin, was identified as the predominant contributor to its genotoxicity. However, for the other three factories, no significant relationship was observed between genotoxicity and detected AOX compounds.     

复合生物阴极型微生物燃料电池处理废水及同步产电性能

为研究生物阴极在MFC（微生物燃料电池）中的应用,分别以粒径为2~4 mm的颗粒活性炭和粒径为2~4、4~8、8~12 mm的颗粒石墨为阴极基质材料,构建升流复合生物阴极型单室MFC,研究阴极基质材料的种类和粒径对MFC的产电性能和净水效能的影响.结果表明:当阳极基质材料为2~4 mm粒径的颗粒活性炭时,燃料电池中利用玻璃纤维取代离子交换膜,阴极基质材料为选用4~8 mm粒径颗粒石墨的反应柱产电量最大,为534 mV（外电阻为1 000 Ω）,最大功率密度达到631.6 mW/m3,库伦效率为3.82%;阴极的pH越低越有利于阴极的产电反应;不同阴极基质材料的MFC对COD_Cr去除率均在80%左右,TN、NH₄+-N及TP的去除率最高可分别达到79%、93%和34%.研究显示,阴极基质材料的种类和粒径对MFC的产电性影响较大,但对其净水效能的影响不大.      

原始红松林退化演替后土壤微生物功能多样性的变化

为了全面了解原始红松林退化演替为次生林后土壤生境及土壤微生物功能多样性的变化规律,以小兴安岭典型的原始阔叶红松林、退化演替后先锋阶段的白桦林及亚顶级阶段的硬阔叶林为研究对象,采用Biolog-ECO微平板检测法,分析三者0~ < 10 cm和10~20 cm表层土的土壤微生物功能多样性变化规律.结果表明:各林型土壤微生物的AWCD值（平均颜色变化率）随培养时间的延长而增加,培养初期表现为原始阔叶红松林>硬阔叶林>白桦林;培养末期表现为原始阔叶红松林>白桦林>硬阔叶林,三者的AWCD值在0~ < 10 cm土层分别为1.06、0.86、0.81,10~20 cm土层分别为0.68、0.47、0.45,原始林显著高于次生林（P < 0.05）,说明原始林土壤微生物对单一碳源的代谢活性显著高于次生林;同一林型下土壤微生物的AWCD值均表现为0~ < 10 cm土层显著高于10~20 cm土层（P < 0.05）. Shannon-Wiener多样性指数、Simpson指数、McIntosh指数和Richness丰富度指数也均表现为原始林显著高于次生林（P < 0.05）.原始林土壤微生物对各类碳源的综合利用强度均大于次生林,不同林型下土壤微生物群落的优势碳源类型存在一定的差异,碳水类、氨基酸类、羧酸类和多聚物类碳源是原始林退化演替后土壤微生物群落在碳源利用上发生变化的敏感碳源.      

Determination of 15 phthalate esters in air by gas-phase and particle-phase simultaneous sampling

Based on previous research, the sampling and analysis methods for phthalate esters (PAEs) were improved by increasing the sampling flow of indoor air from 1 to 4 L/min, shortening the sampling duration from 8 to 2 hr. Meanwhile, through the optimization of chromatographic conditions, the concentrations of 9 additional PAE pollutants in indoor air were measured. The optimized chromatographic conditions required a similar amount of time for analysis as before, but gave high responsivity, the capability of simultaneously distinguishing 15 kinds of PAEs, and a high level of discrimination between individual sample peaks, as well as stable peak generation. The recovery rate of all gas-phase and particle-phase samples of the 15 kinds of PAEs ranged from 91.26% to 109.42%, meeting the quantitative analysis requirements for indoor and outdoor air sampling and analysis. For the first time, investigation of the concentration levels as well as characteristics of 15 kinds of PAEs in the indoor air from four different traffic micro-environments (private vehicles, busses, taxis and subways) was carried out, along with validation of the optimized sampling and analytical method. The results show that all the 9 additional PAEs could be detected at relatively high pollution levels in the indoor air from the four traffic micro-environments. As none of the pollution levels of the 15 kinds of PAEs in the indoor air from the 4 traffic micro-environments should be neglected, it is of great significance to increase the types of PAEs able to be detected in indoor air.